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Transcript
How To | Power over Ethernet
Introduction
Power over Ethernet (PoE) is a technology allowing devices such as IP telephones to receive
power over existing LAN cabling.
This technical note is in four parts as follows:
•
•
•
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PoE Technology
How PoE works
Allied Telesyn PoE implementation
Command Reference
What information will you find in this document?
The first two parts of this document describe the PoE technology, and the installation and
management advantages that PoE can provide. This is followed by an overview of how PoE
works, Power Device(PD) discovery, PD classification, and the delivery of power to PD data
cables. The third part of this document focuses on Allied Telesyn’s implementation of PoE on the
AT-8624PoE switch. The document concludes with a list of configuration and monitoring
commands.
Which product and software version does this information apply to?
The information provided here applies to:
•
•
C613-16048-00 REV C
Products: AT8624PoE switch
Software version: 2.6.5
www.alliedtelesyn.com
PoE Technology
Power over Ethernet is a mechanism for supplying power to network devices over the same cabling
used to carry network traffic. PoE allows devices that require power, called Powered Devices (PDs),
such as IP telephones, wireless LAN Access Points, and network cameras to receive power in
addition to data, over existing infrastructure without needing to upgrade it. This feature can simplify
network installation and maintenance by using the switch as a central power source for other
network devices.
A device that can source power such as an Ethernet switch is termed Power Sourcing Equipment
(PSE). Power Sourcing Equipment can provide power, along with data, over existing LAN cabling to
Powered Devices.
Power Sourcing Equipment (PSE)
Ethernet
Ethernet Switch
7x
8x
9x
1x
2x
3x
10x
11x
12x
7x
8x
9x
4x
5x
6x
1x
2x
3x
10x
11x
12x
4x
5x
6x
C
7 8 9 101112
A
1 2
3
4 5
6
7 8
9
8
#
*
12 34 56
VoIP Phone
A
B
Hub
Webcam
Wireless Access
Point
Powered Devices (PDs)
The advantage of PoE
Most network devices require both a data connection and a power supply. Just as standard
telephones are supplied power and also communicate over the same wiring, now the same
provision can be made for Ethernet network devices.
Some of the advantages of PoE include:
•
•
•
•
•
•
•
•
•
Power over Ethernet
A single cable between switch and Powered Device (PD)
No separate power installation/ connection needed for PD's
Simplified installation and space saving
Device placement is not limited to nearby power sources
PD's can be easily moved to wherever there is LAN cabling
Safety - no mains voltages anywhere
A UPS can guarantee power to devices even during mains failure
Devices can be shut down or reset remotely
Little configuration or management required
2
PoE devices
There are increasing numbers of PoE devices becoming available. The more common uses for PoE
are for communication devices such as VoIP phones and wireless LAN access points. There are
however, quite a variety of devices now taking advantage of PoE technology such as:
•
•
•
•
•
•
•
•
•
•
VoIP phones
Wireless access points
Ethernet hubs
Digital clocks
Webcams
Security cameras
Intercoms
Building access systems
Even a network electric guitar
Plus others…
PoE standard
The Institute of Electrical and Electronics Engineers (IEEE) standardization process involves experts
from many companies, and provides standards for network equipment and protocols that help
retain conformance across the networking industry.
The PoE IEEE 802.3af standard was formally approved by the IEEE Standards Board in June 2003 and
is an amendment to the existing IEEE 802.3 standards.
How PoE works
PoE requires little configuration or management. The PSE automatically determines whether a
device connected to a port is a powered device or not, and can determine the power class of the
device. The PSE can supply up to 15.4 watts of power (at 48 Volts) to the device, while at the same
time providing standard Ethernet network functionality.
Lets look at these concepts in a little more detail:
Power Device (PD) discovery
The first step for PSE equipment (an Ethernet switch for example) is to ascertain whether a device
plugged into a port is a valid Powered Device (PD). If it is, it will require power as well as network
communication through the attached LAN cable.
The IEEE 802.3af-2003 standard for device detection involves applying a DC voltage between the
transmit and receive wire pairs, and measuring the received current. A PSE will expect to see
approximately 25K Ohm resistance and 150nF capacitance between the pairs for the device to be
considered a valid PD. A range around these values is specified in the IEEE 802.3ad standard.
Power over Ethernet
3
The PSE will check for the presence of PD's on connected ports at regular intervals, so power is
removed when a PD is no longer connected.
Power classes
Once a PD is discovered, a PSE may optionally perform PD classification by applying a DC voltage
and current to the port. If the PD supports optional power classification it will apply a load to the
line to indicate to the PSE the classification the device requires.
The power classes as outlined by IEEE 802.3af are as follows:
Class
Power Usage
0
0.44W to 12.95W
1
0.44W to 3.84W
2
3.84W to 6.49W
3
6.49W to 12.95W
4
Reserved for future use
Once the PSE has detected the PD's IEEE 802.3af power class, the PSE can manage the power
allocation by subtracting the PD's class maximum value from the overall power budget. This allows
for control and management of power allocation when there is not enough power available from
the PSE to supply maximum power to all ports.
Any unclassified PD is considered to be a class 0 device.
The IEEE 802.3af standard supports delivery of up to 15.4 watts per port that may be used to
deliver power to PoE devices. This allows quite a variety of possible devices to make use of the
available power.
The maximum power consumed by a PD, as specified by the standard, is 12.95 watts. The system
provides the 'extra' power (up to 15.4 watts) to compensate for line loss.
Some common PoE device power requirements are:
Device
Power Requirement
IP phone
3-6 watts
Wireless access point
4-11 watts
IP security camera
5-12 watts
Power through the cable
An Ethernet cable (CAT5) has four twisted pairs, but only two of these are used for data transfer,
(10/100BASE-TX). The IEEE 802.3af standard allows two options for using these cables for power
supply as follows:
•
•
Power over Ethernet
The spare pairs are used. In this case the unused pairs are used to transfer the power.
The data pairs are used. Since Ethernet pairs are transformer coupled at each end, it is possible
to apply DC power to the centre tap of the isolation transformer without upsetting the data
transfer.
4
The following diagram shows an example of power applied over the data pairs:
Power supplied over the data pins
The IEEE 802.3af standard does not allow both sets of wires to be used, so a choice must be made.
Different vendors PSE equipment may use one or other of the methods to supply power depending
on PoE implementation. So the PSE applies power to either the spare or data wires. The Powered
Device (PD) must be able to accept power from both options.
The voltage supplied is nominally 48V, and a maximum of 12.95W of power is available at the
Powered Device. An isolated DC-DC converter transforms the 48V to a lower voltage more
suitable for the electronics in the Powered Device.
Allied Telesyn PoE implementation
This section is based around the PoE implementation in the new Allied Telesyn AT-8624PoE switch.
The AT-8624PoE is a wire speed Layer 3 fast Ethernet switch.
PoE hardware
The AT-8624PoE switch has a PoE specific chipset inside which performs the various PoE
management tasks and is monitored by the switch CPU. This is made up of two PowerDsine IC's,
which carry out the following functions:
The PD-64012 IC implements all real time activities according to the IEEE 802.3af standard,
including: detection, classification, and port status monitoring. There are two 64012 IC's in the AT8624PoE providing PoE functionality to 12 ports each.
The PD-63000 is an 8-bit microcontroller unit (MCU). The 63000 manages the two 64012 IC's to
free the 8624 switches CPU from this additional task. The AT-8624PoE CPU monitors the 63000
MCU.
Power over Ethernet
5
Power capacity
The PSU in the AT-8624PoE supplies enough power for the switch itself, and has 400 watts available
for PoE provision.
The maximum possible power requirement (24 ports * 15.4W = 370 watts) falls below the
maximum amount of power available (400 watts). This means that you can connect powered
devices to all the ports on the switch (excluding optional expansion ports) without having to be
concerned about exceeding the available power, even if all the PD's require the maximum 15.4
watts.
You can reduce the amount of power a port can source, from the maximum of 15.4 W, using the
command:
set poe [port={port-list|ALL}] [priority={low|high|critical}]
[powerlimit=value]
However, configuring the power limit on the switch will probably not be necessary. As already
mentioned, the power supply in the switch can provide enough power to meet the needs of all 24
10/100 base ports, even if they all require the maximum 15.4 watts for connected PD's.
Power threshold
The switch sends a Simple Network Management Protocol (SNMP) trap to your management
workstation and enters an event in the event log whenever the total power requirements of the
powered devices exceed the specified percentage of the total maximum power available on the
switch. At the default setting of 95%, the switch sends an SNMP trap when the PoE devices require
more than 95% of the maximum available power on the switch.
You can adjust the threshold using the command:
set poe threshold=value
For your management workstations to receive traps from the switch, you must configure SNMP on
the switch by specifying the IP address of the workstations. The switch will also enter an event in
the event log whenever power consumption of the switch has returned below the power limit
threshold.
Power through the cable
As mentioned earlier, the IEEE 802.3af standard describes two methods for implementing PoE over
twisted pair cabling. One method uses the same cables that carry the network traffic and the other
the spare pairs. The PoE implementation on the AT-8624PoE switch transmits power over the same
pairs that carry the network traffic (pairs 1 & 2 and 3 & 6).
Power over Ethernet
6
PoE port management
PoE on the AT-8624PoE switch is enabled by default on all 24 10/100 ports. PoE can be
administratively enabled or disabled on each port using the commands:
DISable POE [POrt={port-list|ALL}]
ENAble POE [POrt={port-list|ALL}]
When PoE is disabled on a port, the port will operate as a normal Ethernet port without delivering
the power to the connected device.
The user can connect either a PD or a non-PD device to a PoE-enabled port without reconfiguring
the port, as PD detection is carried out before any power is supplied to the connected device.
Powered Device (PD) detection
The Allied Telesyn implementation of PoE offers two methods of PD detection. The default is to use
the IEEE 802.3af standard resistance and capacitance measurements as described earlier. The
second option is to support legacy PD's that were designed before the IEEE standard was finalised.
This involves measuring for a large capacitance value to confirm the presence of a PD.
The PD detection method can be set with the command:
SET POE DETECT={IEEE|LEGacy}
In legacy mode, the IEEE method will be tried first and failing the discovery of a valid PD the legacy
capacitance measurement will be tried.
PD detection is carried out in real-time by the PSE controller on each switch port to detect and
monitor the presence of any powered devices. Power is not supplied to any specific port until a
valid PD is detected. A switch port which has a PD unplugged, will cease to have power supplied.
Powered Device (PD) classification
The Allied Telesyn PoE implementation also includes the optional PD power classification
measurement. This is undertaken after PD detection has confirmed a valid PD is attached to a
specific port. The value returned by the power classification measurement is shown when you enter
the command show switch port, but the port is not limited to the classification.
Power Class detection could be used more in future Allied Telesyn products, which are not capable
of supplying the maximum 15.4 watts of power to all ports simultaneously. In this case a 'power
budget' can be implemented to manage how much power is used and how much is still available. For
example, if a device only requires up to 6.5 watts (power class 2) then only this amount is supplied
and taken from the switches total power budget.
Power over Ethernet
7
Port prioritisation
Port prioritisation is the way the switch determines which ports are to receive power in the event
that the needs of the PD's exceeds the available power resources of the switch.
Note: This discussion does not apply to the AT-8624PoE switch, since its power supply can deliver the
maximum of 15.4 W to all 24 10/100 based ports simultaneously. This discussion becomes relevant only if,
at some later date, Allied Telesyn releases a switch with PoE capability that has a power supply that cannot
service all ports simultaneously.
If the PD's connected to a switch require more power than the switch is capable of delivering, the
switch will deny power to some ports based on a system called port prioritisation. You can use port
prioritisation to ensure that PD's critical to the operations of your network are given preferential
treatment by the switch in the distribution of power, should the demands of the devices exceed the
available capacity.
There are three priority levels:
•
•
•
Critical
High
Low
You can set the port priority using the command:
set poe [port={port-list|ALL}] [priority={critical|high|low|}]
[powerlimit=value]
Critical is the highest priority level. Ports set to this level are guaranteed power before any ports
assigned to the other two priority levels. Ports assigned to the other priority levels receive power
only if all the Critical ports are receiving power. Your most critical powered devices should be
assigned to this level. If there is not enough power to support all the ports set to the Critical
priority level, power is provided to the ports based on port number, in ascending order.
High is the second highest level. Ports set to this level receive power only if all the ports set to the
Critical level are already receiving power. If there is not enough power to support all of the ports
set to the High priority level, power is provided to the ports based on port number, in ascending
order.
Low is the lowest priority level. This is the default setting. Ports set to this level only receive power
if all the ports assigned to the other two levels are already receiving power. As with the other levels,
if there is not enough power to support all of the ports set to the Low priority level, power is
provided to the ports based on port number, in ascending order.
Power allocation is dynamic. Ports supplying power to PD's may cease power transmission if the
switch's power capacity has reached maximum usage and new PD's connected to ports with a
higher priority, become active.
Power over Ethernet
8
Visual monitoring
As with other Allied Telesyn switches, there are two LED's on the front panel, which indicate link
status/ activity and duplex mode.
Figure 1: The front panel of the AT-8624PoE
With the AT-8624PoE, there is an additional option to have the duplex LED indicate PoE
information. There is a 'mode' switch to set whether this LED will show Duplex or PoE
information.
If PoE information is selected, this LED indicates whether a Powered Device is connected, fault
condition, and maximum current reached. The LED states in PoE mode are shown below:
PoE Mode
OFF
There is no powered device detected
PD On
Green
The end node is a powered device and the
port is providing power to it
PD Error
Red
The port is experiencing a problem
providing PoE to the end node
Max Current
Flashing Red
The port is connected to a powered device
but providing power to it would exceed
the maximum PoE power budget of the
switch
Software monitoring
There are three 'show' commands available which return information about the PoE settings on the
AT-8624PoE switch.
The 'show switch port=x' command has some additional parameters added, specifying whether PoE
is enabled on the port and any power limit and priority that have been set.
The 'show poe' command details power threshold set, a power usage percentage, and power
consumed by each switch port.
The 'show poe port=x' command details the PoE information for a specified port, including power
limit, power consumed, power class…
Note: All PoE commands are fully detailed in the command reference section following.
Power over Ethernet
9
Command Reference
The following commands are available for configuring and monitoring PoE on the AT-8624PoE
switch:
disable poe port
Syntax
DISable POE [POrt={port-list|ALL}]
Description
This command disables PoE on a port. The port continues to provide
standard Ethernet connectivity even when PoE is disabled. PoE is enabled
by default.
The port parameter specifies a port number, a range of port numbers
(specified as n-m), or a comma-separated list of port numbers and/or
ranges. Port numbers start at 1 and end at 24.The all parameter disables
PoE on all ports.
Examples
To disable PoE on ports 5 and 7, use the command:
disable poe port=5,7
enable poe port
Syntax
ENAble POE [POrt={port-list|ALL}]
Description
This command enables PoE on a port. PoE is enabled by default.
The port parameter specifies a port number, a range of port numbers
(specified as n-m), or a comma-separated list of port numbers and/or
ranges. Port numbers start at 1 and end at 24. The all parameter disables
PoE on all ports.
Examples
To enable PoE on port 2, use the command:
disable poe port=2
set poe detect
Syntax
SET POE DETect={IEEE|LEGacy}
Description
The PoE detect mode allows selection of one of the two modes. In IEEE
mode, only IEEE standard detection is enabled. This is according to IEEE
802.3af standard in which a valid resistance and capacitance is used for
detecting a valid PD.
In LEGacy mode, IEEE detection is first implemented and only if it fails
then legacy detection is used, wherein a large capacitance value is used to
detect a legacy PD. This mode is used to support legacy devices. The
default mode is IEEE mode.
Examples
To set the detection mode to legacy mode, use the command:
set poe detect=legacy
Power over Ethernet
10
set poe port
Syntax
SET POE [POrt={port-list|ALL}]
[POWerlimit=value][PRIOrity={low|high|critical}]
Description
This command sets the PoE settings on a port.
Parameter
port
Description
Sets PoE on a specific port number, a range of port
numbers (specified as nm), or a comma-separated list
of port numbers and/or ranges. Port numbers start at
1 and end at 24. Specifying all sets PoE on all ports.
priority
Determines which ports receive PoE when powered
device consumption exceeds the available power
resources of the switch. One of Low, High, or
Critical. Default: Low
powerlimit
The maximum amount of power (in milliwatts) a
powered device can draw from the port.
Default: 15400mW (15.4W)
Examples
To set the priority on ports 6 and 11 to high, use the command:
set poe port=6,11 priority=high
To set the maximum power on port 14 to 12,500 mW, use the command:
set poe port=14 powerlimit=12500
set poe threshold
Syntax
SET POE THReshold=value
Where threshold is specified as a percentage of the total amount of PoE
available. The range is 1 to 100
Description
The switch sends an SNMP trap to the management workstation and
enters an event in the event log when the total power requirements of
the powered devices exceeds the specified percentage of the total
maximum power available on the switch. The switch sends an SNMP trap
when the PoE devices require more than 95% (the default) of the
maximum available power on the switch. The threshold is adjustable.
Examples
To set the threshold to 80% of the available power, use the command:
set poe threshold=80
Power over Ethernet
11
show poe
Syntax
SHow POE [PORt={port-list|ALL}]
Where port specifies a port number, a range of port numbers (specified
as n-m), or a comma-separated list of port numbers and/or ranges. Port
numbers start at 1 and end at 24.
Description
This command displays information about Power over Ethernet for the
specified port or ports. If no port number is specified, summary
information about all PoE ports is displayed. If a port, or range of ports is
specified, more detailed information is displayed. If all is specified, detailed
information about all Power over Ethernet ports is displayed
Example output from the SHOW PoE command:
Manager > show poe
PoE Global Power Status:
Max Available Power....400 W
Power Threshold........95 percent
Consumed Power.........0 W
Available Power........400 W
Power Usage............0.00 percent
Power Detect Mode......IEEE
Min Shutdown Voltage...44.0 V
Max Shutdown Voltage...57.0 V
PoE All Ports Power Status Summary:
Port
PoE Status
Consumed Power(mW)
Power State
--------------------------------------------------------------------1
ENABLED
0
OFF - Detection in process
2
ENABLED
0
OFF - Detection in process
3
ENABLED
0
OFF - Detection in process
4
ENABLED
0
OFF - Detection in process
5
ENABLED
0
OFF - Detection in process
6
ENABLED
0
OFF - Detection in process
7
ENABLED
0
OFF - Detection in process
8
ENABLED
0
OFF - Detection in process
9
ENABLED
0
OFF - Detection in process
10
ENABLED
0
OFF - Detection in process
11
ENABLED
0
OFF - Detection in process
12
ENABLED
0
OFF - Detection in process
13
ENABLED
0
OFF - Detection in process
14
ENABLED
0
OFF - Detection in process
15
ENABLED
0
OFF - Detection in process
16
ENABLED
0
OFF - Detection in process
17
ENABLED
0
OFF - Detection in process
18
ENABLED
0
OFF - Detection in process
19
ENABLED
0
OFF - Detection in process
20
ENABLED
0
OFF - Detection in process
21
ENABLED
0
OFF - Detection in process
22
ENABLED
0
OFF - Detection in process
23
ENABLED
0
OFF - Detection in process
24
ENABLED
0
OFF - Detection in process
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www.alliedtelesyn.com
© 2005 Allied Telesyn Inc. All rights reserved. Information in this document is subject to change without notice. All company names, logos, and product designs that are trademarks or registered trademarks are the property of their respective owners.
C613-16048-00 REV C
